1.
Relaxation of Levitation Force of the YBCO Bulk above Permanent Magnet Guideway;
永磁外场中高温超导体悬浮力弛豫的研究
2.
Stress relaxation characteristics of several kinds of rubber and their compounds used in tire tread
几种胎面用橡胶及其混炼胶的应力弛豫特性
3.
AN EXPERIMENTAL RESEARCH FOR THE RESIDUAL STRESS MEASURE BY STRESS RELAXATION METHOD IN CYLINDER CAP
应力弛豫法测定内燃机气缸盖残余应力的实验研究
4.
Mechanical and Impedance Relaxations Study in Na_xCo_2O_4
Na_xCo_2O_4陶瓷的力学弛豫和阻抗弛豫研究
5.
Relaxational and Mechanical Behavior of DOP-plasticized PMMA
DOP增塑PMMA的弛豫和力学行为
6.
Study on the Mechanical Relaxation Behaviors of Cu-based Shape Memory Alloys;
铜基形状记忆合金力学弛豫行为的研究
7.
Dielectric relaxation properties of PMN-PT single crystals under hydrostatic pressure
等静压力诱导的PMN-PT单晶介电弛豫特性研究
8.
Snoek Relaxational Peak in a Fe-Cr-Al Alloy;
Fe-Cr-Al合金中的Snoek弛豫
9.
Investigation of excited triplet absorption spectrum and relaxation kinetics of dimeric chlorophyll a
叶绿素α二聚体激发三重态吸收谱及其弛豫动力学过程的研究
10.
The Ultrafast Vibrational Relaxation and Internal Conversion Dynamics of the Polyatomic Molecules in Liquids Studied in Femtosecond Laser Pulse;
飞秒强激光场中液相多原子分子的振动弛豫和内转换动力学研究
11.
Pressure Effect on Structural Relaxation and Mechanical Properties of LaAlCuNi Bulk Metallic Glass
高压等温处理后LaAlCuNi大块非晶的结构弛豫及其压痕下力学行为
12.
Vibrational energy relaxation in condensed phases is an important dynamical process in chemistry, physics and biology.
凝聚相中的振动能量弛豫是化学、理学和生物学中一个非常重要的动力学过程。
13.
A bimolecular decay is used to explain the dependence of dynamics of the Kerr signal on the incident light intensity.
一个双激发子弛豫机制被用来解释克尔信号动力学特性对入射光强度的依赖性。
14.
DYNAMICAL MECHANICAL AND DIELECTRIC STUDY ON THE MOTION OF THE PEDANT CHAINS IN NETWORK COPOLYMER CASTOR OIL/TDI+HEMA
动态力学及介电法研究蓖麻油丙烯酸酯共聚网络悬挂链的弛豫运动
15.
Studies on Molecular Dynamics in Aqueous Solution of Superparamagnetic Iron Oxide Nanoparticales and Surfactants by Proton NMR Transverse Relaxation Dispersion;
顺磁纳米颗粒及表面活性剂水溶液体系的动力学特性的NMR横向弛豫分散研究
16.
The nuclei can relax to their normal distribution.
核子可以弛豫到它们正常分布状态。
17.
A new relaxation oscillation mode is found through the dynamic simulation.
通过模拟发现了新的弛豫振荡模式。
18.
The relaxation is due to the interactions with the thermal excitations.
弛豫是由热激发相互作用而产生。